**4. Conclusions**

In the present work, a full laser-based manufacturing technique is proposed. According to the attained results, the following conclusions are drawn:


**Author Contributions:** Conceptualization and methodology, J.I.A.; LMD experiments, M.C.; engraving experiments, J.I.A.; polishing experiments, J.E.R.; Analysis of the obtained data, J.I.A., M.C. and J.E.R.; Writing-Original Draft Preparation, J.I.A.; Supervision, A.L.

**Acknowledgments:** Special thanks are addressed to the Industry and Competitiveness Spanish Ministry for the support on the DPI2016-79889-R INTEGRADDI project and PARADDISE project H2020-IND-CE-2016-17/H2020-FOF-2016 of the European Union's Horizon 2020 research and innovation program.

**Conflicts of Interest:** The authors declare no conflict of interest.

#### **Appendix A**

Process parameters for LBM tests carried out to determine the optimal parameters are detailed in Table A1. In all tests, the hatching parameters are kept constant according to the values detailed in Table 4 (line spacing of 0.05 mm and 20 hatching with an angle increment of 17◦). Test codes for the LBM tests are named with upper case letters.


**Table A1.** LBM process parameters.


**Table A1.** *Cont.*

#### **Appendix B**

Process parameters for LP are shown in the following Table A2. In all tests, the line spacing is kept constant with a value of 0.02 mm. The angle increment between the hatchings is defined to sweep a total angle of 360◦ with the defined number of hatches. Test codes for the LP tests are named with lower case letters.




**Table A2.** *Cont.*

#### **References**


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